RU2190931C2 - Device and method for separating common forward channels in cdma communication system - Google Patents

Abstract

FIELD: code- division multiple-access communication systems, in particular those of second and third generations. SUBSTANCE: device designed in particular for use in systems of second and third generations to separate Walsh code assigned to common forward channel IS-95 and Walsh code assigned to common forward channel IMT-2000, respectively, has plurality of channel transmitters, memory medium carrying orthogonal code numbers for common forward channel used in second CDMA communication system and orthogonal code numbers which cannot support orthogonality because of code used by common forward channel at maximal data transmission speed, orthogonal code being used in first CDMA communication system, as well as controller to read orthogonal code out of memory medium according to information coming from mobile station about its type and assignment of particular common forward channel so that message passed through common forward channel is expanded and conveyed by one of respective channels transmitters using one of particular orthogonal code numbers read out. EFFECT: enhanced effectiveness of using mentioned codes. 30 cl, 9 dwg

Description

FIELD OF THE INVENTION
The present invention relates generally to a CDMA communication system (multiple access to code division multiplexing) and, in particular, to a device and method for allocating direct common channels in systems of 2 generations (IS-95) and 3 generations (IMT-2000).

State of the art
In order to increase the channel capacity, the CDMA (Code Division Multiple Access) communication system divides the channels using orthogonal codes. For example, the IS-95 system's forward link performs channel separation using orthogonal codes. The reverse link may also perform channel separation using orthogonal codes by time equalization. An example of an orthogonal code that is commonly used is the Walsh code. The number of available orthogonal codes is determined depending on the modulation method and the minimum data rate.

 The IS-95 direct common channel, which separates the channels using fixed orthogonal codes, comprises a pilot channel, a synchronization channel, and a paging channel. The pilot channel uses the 0th Walsh code (which is the Walsh code having a Walsh number 0), the synchronization channel uses the 32nd Walsh code, and the paging channel uses the 1st to 7th Walsh codes. In an existing IS-95 system having the above channel structure, all channels have a relatively short frame length and, therefore, always use the same Walsh codes of the same length (for example, 64 chips).

 However, in the IMT-2000 system there are many frames for transmitting data that have a large number of information bits, so that there may be several channels having Walsh codes having a shorter length (or expansion coefficient). For example, an additional channel may use a shorter Walsh code to transmit data at high speed. The traffic data transmitted by the supplemental channel may contain moving image information (eg, channel data) to be transmitted in real time and general packet data. Such traffic data may be transmitted at variable data rates. For example, an additional channel may support data rates of 9.6 Kbps, 19.2 Kbps, 38.4 Kbps, 76.8 Kbps, 153.6 Kbps, 307.3 Kbps and 614.4 Kbps. Walsh codes have lengths (or expansion coefficients) of 256, 128, 64, 32, 16, 8, and 4 in accordance with the corresponding data rates.

 Additionally, the direct common control channel (P-CAM) of the IMT system also supports variable data rates. For example, a common control channel may support data rates of 9.6 Kbps, 19.2 Kbps, and 38.4 Kbps. Here, the Walsh code has Walsh lengths (or expansion coefficients) of 256, 128, and 64 in accordance with respective data rates.

 In a variable bit rate channel scheme, a channel frame is transmitted at one of the specific data rates, and the data rate may change during the transmission of the frame in accordance with a change in the channel environment. For example, if the channel environment improves during data transfer at a data rate of 19.2 Kbit / s, the data transfer rate can be changed to higher data rates from 38.4 Kbit / s to 614.6 Kbit / s. Otherwise, if the channel environment is degraded, the data rate may change to a lower data rate of 9.6 Kbps. Here, the channel environment refers to any factor that may influence data transmission. An increase in the data rate in accordance with the channel environment causes a decrease in the Walsh length, thereby making it difficult to assign a Walsh code, as described below with respect to FIG. 3. Before describing these problems, reference will be made to the structure of the Walsh codes depicted in FIG. 1 and FIG. 2.

 Figure 1 depicts the structure of a conventional set of Walsh codes. Referring to FIG. 1, the set W of Walsh codes consists of N Walsh codes having a length of N Walsh, and can be divided into 4 sets of Walsh codes of length N / 2. If it is assumed that a set of N / 2 Walsh codes having a length of N / 2 Walsh is defined as a set W 'of Walsh codes, two upper sets of Walsh codes of length N / 2, each is equivalent to a set of W' Walsh codes. In addition, the lower left set of Walsh codes of length N / 2 is equivalent to the above set of Walsh codes W ', and the lower right set of Walsh codes of length N / 2 is equivalent to the inverted set of Walsh codes W'. To invert the Walsh code, bit “1” is converted to “0”, and bit “0” to “1”.

 Equation (1) below shows how to obtain a set of Walsh codes of length 4 from a plurality of Walsh codes of length 2, for a better understanding of the structure of the Walsh codes of FIG. 1. That is, a set of Walsh codes of length 4 corresponds to the aforementioned set of W, and a set of Walsh codes of length 2 corresponds to the aforementioned set of W Walsh code.

Фиг. 2 изображает набор кодов Уолша длиной 256, который получается в способе по уравнению (1). Ссылаясь на фиг.2, набор W кодов Уолша состоит из 256 кодов Уолша, имеющих длину Уолша 256, и может быть разделен на 4 набора кодов Уолша длиной 128. Если предположить, что набор из 128 кодов Уолша, имеющих длину Уолша 128, определяется как набор W' кодов Уолша, два верхних набора кодов Уолша длиной 128, каждый эквивалентен дважды повторенному набору W' кодов Уолша. Кроме того, нижний левый набор кодов Уолша длиной 128 эквивалентен вышеупомянутому набору кодов Уолша W, а нижний правый набор кодов Уолша длиной 128 эквивалентен инвертированному набору

кодов Уолша.

FIG. 2 depicts a set of Walsh codes of length 256, which is obtained in the method according to equation (1). Referring to FIG. 2, a set of Walsh codes W consists of 256 Walsh codes having a Walsh length of 256 and can be divided into 4 sets of Walsh codes of 128 length. Assuming a set of 128 Walsh codes having a Walsh length of 128 is defined as a set of W 'Walsh codes, two upper 128 sets of Walsh codes of length 128, each equivalent to a twice repeated set of W' Walsh codes. In addition, the lower left set of Walsh codes of length 128 is equivalent to the aforementioned set of Walsh codes of W, and the lower right set of Walsh codes of length 128 is equivalent to the inverted set

Walsh codes.

кодов Уолша. Здесь структура набора W' кодов Уолша обычно применяется ко всем наборам W кодов Уолша, составляющим набор W' кодов Уолша. Кроме того, набор

кодов Уолша также конструируется таким же образом, как набор W' кодов Уолша, как раскрыто выше. При использовании такой структуры кодов Уолша возможно уменьшение взаимного влияния (или корреляции) пользователей.Furthermore, assuming that a set of 64 Walsh codes having a Walsh length of 64 is defined as a set of W "Walsh codes, two upper sets of Walsh codes of length 64 of each set of W" Walsh codes, each is equivalent to a twice repeated set of W "Walsh codes. in addition, the lower left Walsh code set of length 64 of each set of W "Walsh codes is equivalent to the upper set of W" Walsh codes, and the lower right set of Walsh codes of length 64 is equivalent to the inverted set

Walsh codes. Here, the structure of the set of W 'Walsh codes is typically applied to all sets of W Walsh codes constituting the set of W' Walsh codes. Also set

Walsh codes are also constructed in the same way as a set of W 'Walsh codes, as disclosed above. Using this structure of Walsh codes, it is possible to reduce the mutual influence (or correlation) of users.

 FIG. 3 depicts the mutual influence of two users according to Walsh codes if the data rate changes in accordance with the environmental conditions of the channel. Referring to FIG. 3, the first user uses the 8th Walsh code (which is the Walsh code having Walsh number 8) with a data rate of 38.4 Kbps. A Walsh code of length 64 should be used to transmit data at a data rate of 38.4 Kbps, as described above. Consequently, the data of the first user is expanded by the 8th Walsh code of length 64 and is transmitted at a data rate of 38.4 Kbps. With this data rate, it is possible to transmit 4 times the data that can be transmitted at a data rate of 9.6 Kbps. This becomes apparent when compared with the fourth user’s data transmission method, which transmits data at a data rate of 9.6 Kbps using the 8th Walsh code of length 256. More specifically, with respect to the first user data transmission method, the first code symbol is expanded the first Walsh code of 64 chips (i.e., the first 64 chips of the 8th Walsh code), the second code symbol is expanded with a second Walsh code of 64 chips (i.e., the second 64 chips of the 8th Walsh code). The third code symbol is expanded with a third Walsh code of 64 chips (i.e., the third 64 chips of the 8th Walsh code) and the fourth code symbol is expanded with a fourth Walsh code of 64 chips (i.e. the fourth 64 chips of the 8th Walsh code).

 The second user uses the 8th Walsh code with a data rate of 19.2 Kbps. A 128 Walsh code should be used to transmit data at a data rate of 19.2 Kbps. Therefore, the data of the second user is expanded by the 8th Walsh code of length 128 and transmitted at a data rate of 19.2 Kbps. With this data rate, it is possible to transmit 2 times the data that can be transmitted with a data rate of 9.6 Kbps. This becomes apparent when compared with the fourth user’s data transmission method, which transmits data at a data rate of 9.6 Kbps using the 8th Walsh code of length 256. More specifically, with respect to the second user data transmission method, the first code symbol is expanded the first Walsh code of 128 chips (i.e., the first 128 chips of the 8th Walsh code), and the second code symbol is expanded with a second Walsh code of 128 chips (i.e. the next 128 chips of the 8th Walsh code) .

 The third user uses the 72nd Walsh code with a length of 128 with a data rate of 19.2 Kbps. Two transmission symbols are expanded with the corresponding Walsh code of 28 chips (72 Walsh code).

 In addition, from the fourth to the seventh users use their unique Walsh codes with a length of 256 with a data transfer rate of 9.6 Kbps. Each transmission symbol is extended by a Walsh code of 256 chips. The unique Walsh codes used by fourth through seventh users are the 8th, 72nd, 136th and 200th Walsh codes, respectively.

 Next, reference will be made to the mutual influence between users using different data rates and Walsh codes.

 First, a description will be made of the mutual influence between the first user and the third user based on a block of 64 chips. The first character of the first user and the corresponding duration of the third user are expanded by the same Walsh code W "8, thus causing mutual influence between the first user and the third user. That is, with the corresponding duration, the first user has a mutual influence with the third user. This mutual influence also occurs when the duration of the third character of the first user and the corresponding duration of the third user. It is not possible to transmit third-user data

 Next, a description will be made of the mutual influence between the first user and the fifth to seventh users based on a block of 64 chips. The first character of the first user and the corresponding duration from fifth to seventh users are expanded by the same Walsh code W "8, thereby causing mutual influence between the first user and fifth to seventh users. That is, with the corresponding duration of the elementary signal, the first user has a correlation from fifth to seventh users This correlation also occurs when the duration of the third character of the first user and the corresponding duration of the fifth user signal Vatel at the second symbol duration of the first user and the corresponding chip duration of the sixth user and the fourth symbol duration of the first user and the corresponding duration of the seventh user elementary signal. Thus, when the first user data transmission can not transmit data from the fifth to seventh users.

In other words, if there is a user using a short Walsh code, such as the first user, users using longer Walsh codes cannot use some Walsh codes due to a poor correlation property. For example, if there is a user using the nth Walsh code W _n (0≤n <64) of length 64 for a Walsh code of full length 256, a user using a large Walsh length cannot use not only the _nth Walsh code W, but also the (n + 64) th, (n + 128) th and (n + 192) th Walsh codes. That is, several Walsh codes cannot be used due to one user. Here, an increase in the user data rate will cause a decrease in the Walsh length, thereby increasing the number of invalid Walsh codes. If a specific Walsh code is determined, it is possible to create a group of Walsh codes having Walsh numbers that cannot be used due to poor correlation for the length of a specific Walsh code. The Walsh code group is called the Walsh pool.

 Under these circumstances, if the paging channel of the IMT-2000 system uses Walsh codes 1 through 7, it is not possible to use data channels having Walsh lengths 4 and 8 of 256 Walsh codes of length 256 for the reason described with reference to FIG. 3 .

SUMMARY OF THE INVENTION
Thus, an object of the present invention is to provide a device and method for separately using the Walsh code assigned to the direct common channel IMT-2000 and the Walsh code assigned to the direct common channel IS-95 to increase the efficiency of using Walsh codes in a CDMA communication system.

 Another objective of the present invention is to provide a base station device for a CDMA communication system that contains a direct common channel IS-95 and a direct common channel IMT-2000 and guarantees a variable speed channel for a direct common channel IMT-2000 using the Walsh code from the Walsh pool, and a method for controlling this device.

 A further further object of the present invention is to provide a mobile station device that can communicate with a base station device that contains a direct common channel IS-95 and a direct common channel IMT-2000 and guarantees a variable rate channel for a direct common channel IMT-2000 using a code Walsh from the Walsh pool, and a way to control this device.

 Another objective of the present invention is to provide a device and method for separately allocating direct common channels of various communication systems mdcr, 2 generations and 3 generations.

 To solve the above problems, a device for allocating a direct common channel in a communication system mdcr. A device for allocating a direct common channel in a CDMA communication system (code division multiple access), comprising a plurality of channel transmitters, a storage medium for storing, as orthogonal code numbers for a direct common channel used in the second CDMA communication system, orthogonal code numbers that cannot maintain orthogonality due to the orthogonal code that the forward common channel uses at the maximum data rate, and the orthogonal code is used in the first CDMA communication system, and a controller for reading the orthogonal code numbers from the storage medium in accordance with the type information of the mobile station and allocating a specific direct common channel so that the direct common channel message is expanded and transmitted by the corresponding one of the channel transmitters with a specific one of read orthogonal code numbers.

Brief Description of the Drawings
The above and other objects, features and advantages of the present invention will become more apparent from the following detailed description when taken in conjunction with the accompanying drawings, in which:
figure 1 is a diagram illustrating the structure of a common set of Walsh codes;
FIG. 2 is a diagram illustrating a set of Walsh codes having a Walsh length of 256;
FIG. 3 is a diagram for explaining the mutual influence appearing between users if Walsh codes are assigned in a conventional manner;
FIG. 4 is a flowchart illustrating how an IMT-2000 base station shares paging channel information with an IMT-2000 mobile station;
5 is a block diagram illustrating a circuit for controlling channel transmitters using a Walsh pool, in accordance with an embodiment of the present invention;
6 is a block diagram illustrating one of the channel transmitters of figure 5;
FIG. 7 is a flowchart illustrating a procedure for allocating a paging channel in the controller of FIG. 7, in accordance with an embodiment of the present invention;
FIG. 8 is a block diagram illustrating a channel receiver of a mobile station that corresponds to channel transmitters (520-526) of FIG. 5; and
FIG. 9 is a flowchart illustrating a procedure for allocating a paging channel in the controller of FIG.

A detailed description of the preferred
example implementation
A preferred embodiment of the present invention will be described hereinafter with reference to the accompanying drawings. In the following description, well-known functions or constructions are not described in detail since they would obscure the invention with unnecessary details.

 The terms "orthogonal extension" and "channel extension", as used here, have the same meaning, and the terms "orthogonal code and Walsh code", which are used here, also have the same meaning. In addition, the term "user" refers to a subscriber requiring a data transfer, and refers to the data of the corresponding channel from a system point of view.

 4 is a flowchart for explaining how a base station (BS) uses paging channel information in conjunction with a mobile station (MS) in a second (i.e., IMT-2000) CDMA communication system. Referring to FIG. 4, the base station constantly transmits a paging message containing information about the number of paging channels currently used for each mobile station within its cell area through the primary paging channel. After power is turned on or a new base station enters the cell area of the cell, the mobile station monitors the primary paging signal transmitted from the base station. The message transmitted through the paging channel contains information about the paging channel currently used by the base station. The paging channel information may comprise the number of paging channels for the IMT-2000 mobile station or the Walsh number of all paging channels for the IMT-2000 mobile station. Thus, after receiving the message from the base station, the mobile station determines the paging channel to use. Several methods have been proposed for determining the paging channel, but the paging channel is usually determined using a hash function. More specifically, the mobile station hashes its electronic serial number (EPN), which is a unique number using the hash function, and then determines the paging channel and time interval in accordance with the hashed number. Here, the electronic serial number is used to identify the mobile station. In addition, the determination of the paging channel and the time interval is equivalent to the determination of the Walsh code for allocating the paging channel. After determining the paging channel and the time interval, the mobile station sends a registration message (or response message) to the base station through the access channel in confirmation of the paging channel message. The registration message contains the type and electronic serial number of the mobile station. After receiving the registration message from the mobile station, the base station recognizes the type of mobile station, and then determines the paging channel used by the mobile station. Finally, the base station hashes the electronic serial number of the mobile station using the hash function and determines the paging channel and the time interval that the mobile station determines using the hashed number. Since the base station and the mobile station usually have a hash function, the same results are provided when determining the paging channel by hashing the same unique number. Thus, when the paging channel used by the base station and the mobile station is determined, the base station sends a control message to the mobile station through a specific paging channel.

 5 depicts a device for allocating a paging channel when using the Walsh pool for a paging channel of an IMT-2000 communication system and controlling data transmission through a dedicated paging channel. The device separately controls the Walsh code used to allocate the paging channel in the first CDMA communication system (i.e., IS-95) and the Walsh code used to allocate the paging channel in the second CDMA communication system (i.e., IMT-2000).

 Referring to FIG. 5, the memory 502 separately stores the Walsh code number for the first CDMA communication system and the Walsh code number for the second CDMA communication system. That is, memory 502 stores numbers 1 through 7 of the Walsh codes for a CDMA communication system. Otherwise, the memory 502 stores the Walsh paging pool, consisting of Walsh code numbers identified by one of the numbers 1 through 7 of the Walsh codes for the second CDMA communication system. The Walsh paging pool stored in the memory 502 consists of a Walsh number corresponding to the paging channel that is commonly used with the first CDMA communication system, and also contains many Walsh examples determined depending on the Walsh length based on the above Walsh number corresponding to the paging channel. In addition, the memory 502 provides a Walsh pool stored therein under the control of the controller 500. For example, it is assumed here that the Walsh code of the Walsh codes used in the first CDMA communication system has a Walsh number 1 (Walsh number of the primary paging channel) and a Walsh length 16. In this case, the Walsh paging numbers that can be determined have a Walsh code number of 1 and the Walsh lengths are (1, 17, 33, 49, 81, 97, 113). Memory 502 stores all Walsh code numbers corresponding to certain Walsh paging numbers in the form of a Walsh pool. Of course, the Walsh paging pool must contain any of the numbers 1 through 7 of the Walsh code used in the first CDMA communication system.

 When a mobile station requests paging, paging information, i.e. information about the mobile station is provided to the controller 500. The paging information contains the type and unique number of the mobile station that requests paging.

 After receiving the paging channel information, the controller 500 recognizes the type of mobile station from the received information. At this point, if it is decided that the mobile station is the mobile station for the first CDMA communication system (i.e., IS-95 mobile station), the controller 500 reads the Walsh pool for the Walsh paging number of the first CDMA communication system from the memory 502. In addition, , the controller 500 provides the paging channel transmitters 520-526 with a control message for the paging channel and the time interval used by the mobile station using the unique number of the mobile station that requests paging in accordance with the input information atsiey. The paging channel allocation procedure in the controller 500 is illustrated in FIG. 7.

 When the controller 500 outputs a control message for the paging channel and the time interval used by the mobile station, the paging channel transmitters 520-526 receive the corresponding Walsh codes and time intervals from the controller 500, the input signals 1-data 2 with the corresponding Walsh codes are expanded, and extended signals are output as a transmission message. In the case where the paging transmitters are designed such that the Walsh numbers are constantly assigned to the respective channel transmitters, the Walsh number is determined when the used paging is determined. For the IS-95 mobile station, the control message is provided to the channel transmitters in the IS-95 paging channel unit, and for the IMT-2000 mobile station, the control message is provided to the channel transmitters in the IMT-2000 paging channel unit at the corresponding time intervals of the paging channel, determined by the hashing of the unique mobile station numbers.

 When messages sent to several mobile stations are collected as described above, transmission messages output from the respective channel transmitters 520-526 are summed by adder 540 and then multiplied by a pseudo noise (PN) sequence by multiplier 550.

 Meanwhile, in the embodiment, a description is made for generating a Walsh pool (Walsh paging pool) including a priority paging channel (Walsh number 1) to re-number the Walsh number used in the six remaining paging channels in the Walsh pool numbers.

 However, in the first CDMA communication system (IS-95), the Walsh number used in the paging channel, as well as the Walsh number of the pilot channel and the Walsh number of the synchronization channel, are constant. Since the second CDMA communication system is backward compatible with the IS-95 system, the orthogonal number of the pilot channel and the synchronization channel in the IMT-2000 system must be constant in the same way as in the IS-95 system.

 Thus, in the case of fixing numbers of the orthogonal code, such as, for example, channels for high speed data processing of the additional channel, all the numbers of the paging channel can be renumbered in the numbers existing in the Walsh paging pool. However, in a method other than the Walsh paging pool, another Walsh pool containing the orthogonal code number used in the synchronization channel and the orthogonal code number used in the pilot channel can be generated in the same manner as above. And, therefore, the Walsh paging pool and the other Walsh pool have, respectively, orthogonal numbers different from each other. Thus, in the IMT-2000 system, in addition to the priority paging channel orthogonal code number, the pilot channel orthogonal code number and the synchronization channel orthogonal code numbers included in the said Walsh pool, the numbers of other paging channels that should fix the orthogonal numbers are six .

 At this time, it is possible to divide and fix the orthogonal numbers of the remaining paging channels, which should be fixed, in the orthogonal numbers of the two Walsh pools. Thus, a Walsh pool that can transmit data having a short Walsh code can be re-numbered significantly more.

 FIG. 6 depicts the structure of channel transmitters 520-526 of FIG. 5 as an example. Referring to FIG. 6, a tail bit generator 602 generates 8 tail bits to indicate the end of a control message frame and sums the generated tail bits with the added cyclic redundancy code (CRC) data provided from a cyclic redundancy code generator not shown in the figure. Channel encoder 604 encodes a signal output from the tail bit generator 602. For channel encoder 604, a convolutional encoder or turbo encoder is typically used. An interleaver 606 interleaves the symbol data output from the channel encoder 604. A signal converter 610 converts the signal level output from the interleaver 606. A multiplier 610 multiplies the signal output from the signal converter 608 by an orthogonal code for orthogonal spreading of the input signal.

 A detailed description will now be made of an embodiment of the present invention. An embodiment includes a method for generating a Walsh paging pool and a method for allocating a paging channel using the generated Walsh pool.

First, a detailed description will be made of a method for generating a Walsh pool consisting of Walsh numbers used to assign a paging channel in a first CDMA communication system. If there is a user using the nth Walsh code (0≤n <64) of length 64 Walsh, where the total length of the Walsh code is 256, the user using the long Walsh code cannot use the (n + 64) th, (n + 128) th and (n + 192) th codes W _{n + 64} , W _{n + 128} and W _{n + 192} Walsh, as well as the n-th code W _n Walsh.

If the Walsh length for the maximum primary user data rate is L and the nth Walsh code is used, the set {W _{n +} iL | 0≤i <(256 / L)}, where i is an integer, will be called the Walsh pool. Although the total Walsh length is limited to 256, in the embodiment, the total Walsh length is variable. In this case, where the Walsh length is 64, the Walsh pool is {W _n , W _{n + 64} , W _{n + 128} , W _{n + 192} }.

 In general, the paging channel numbers that can be shared with the IS-90 communication system are 1 to 7. Since Walsh number 1 is used for the main paging channel, Walsh number 1 is assigned when only one paging channel is required, the 1st and 17th 1st Walsh codes can be assigned when two IMT-2000 paging channels are required; and the 1st, 17th and 33rd Walsh codes can be assigned when three IMT-2000 paging channels are required, so that the transmission of additional channels having a short Walsh length becomes possible.

 For example, the Walsh paging pool for the IMT-2000 system may include a set of Walsh numbers {1, 17, 33, 49, 81, 97, 113}, where Walsh number 1 is the number for the primary paging channel, and the remaining Walsh numbers are defined as n + iL (where n is the Walsh number for the main paging channel, L is the Walsh length, ai is an integer less than 256 / L).

 For L = 16, the Walsh pool '1 + i16' contains the Walsh code number having a Walsh number of 65 (for i = 4). However, since the IS-95 system primarily uses Walsh number 1 for the paging channel and uses a Walsh code of length 64, the 65th Walsh code and the 1st Walsh code are recognized as the same Walsh code. The existing IS-95 system uses 64 Walsh codes of length 64. If the IS-95 mobile station is located in the cell area of the IMT-2000 system and the IMT-2000 system provides the IMT-2000 mobile station with paging information using the 65th Walsh code, the mobile station IS-95 receives a signal combined from the paging information provided by the 65th Walsh code and the paging information provided by the 1st Walsh code. Thus, the paging information provided by the 1st Walsh code may be subject to significant interference. Therefore, the Walsh pool for the IMT-2000 paging channel contains 7 Walsh numbers, including Walsh number 65. The number of Walsh codes in a Walsh paging pool is initially set to a maximum of 7 base stations. Since the order of use of the Walsh codes can be determined in advance, the mobile station can recognize the Walsh paging pool if the number of paging channels used by the base station is known. That is, when the base station uses only one paging channel, Walsh number 1 is used; when the base station uses two paging channels, Walsh numbers 1 and 17 are used; and when the base station uses three paging channels, Walsh numbers 1, 7, and 33 are used if the procedure for using the Walsh code number is {1, 17, 33, 49, 81, 97, 113}, as mentioned above.

 Next will be made a detailed description of the purpose of the paging channel with reference to Fig.7. At operation 700, the controller 500 receives paging information containing information about the type of mobile station that requests paging from the mobile station through the access channel. The base station may confirm the type of mobile station with a registration message received via the access channel. After receiving the paging information, the controller 500 analyzes the type of mobile station that is currently requesting paging according to the paging information in step 710. Through analysis, the controller 500 determines whether the mobile station is an IMT-2000 mobile station or an IS-95 mobile station. That is, the controller 500 determines whether the mobile station that transmitted the paging channel information through the access channel is a mobile station for the first CDMA communication system or a mobile station for the second CDMA communication system. When it is determined in step 710 that the mobile station is an IS-95 mobile station, the controller proceeds to step 750 to read the Walsh code number for the IS-95 paging channels from the memory 502. Here, the Walsh code number for the IS-95 paging channels is read from the memory 502 is the Walsh code number that is commonly used in the first CDMA communication system. They are from the 1st to the 7th Walsh codes. However, when it is determined in step 710 that the mobile station is an IMT-2000 mobile station, the controller 500 proceeds to step 755 to read the Walsh code number for the IMT-2000 paging channels from the memory 502 in accordance with the paging information. Here, the Walsh code numbers read from memory 502 are located in the elements of the Walsh paging pool.

 Meanwhile, after reading the Walsh numbers at operations 750 and 755, the controller 500 analyzes the unique number of the mobile station from the paging information received from the mobile station at operation 720. After recognizing the unique number of the mobile station through analysis, the controller 500 calculates the hashed number using the hash function when step 730. The used hash function should be identical to the hash function used in the mobile station. After calculating the hashed number, the controller 500 determines the Walsh number and time interval for allocating a paging channel for the mobile station in accordance with the calculated hashed number for generating a control message in operation 740. The control message is used to allocate paging channels for channel transmitters 520-526.

 As described above, in one embodiment of the present invention, a high data service speed can be achieved by using the Walsh code of the paging channel without changing the IS-95 system and using the Walsh paging pool in the IMT-2000 system.

 FIG. 8 shows a channel receiver of a mobile station that corresponds to channel transmitters 520-526 of FIG. 5. Referring to FIG. 8, a mobile station receives a paging message from a base station through a primary paging channel (which is a paging channel assigned with a 1st Walsh code), as shown in FIG. Controller 800 examines the number of paging channels that can be allocated at the base station using the paging message. The controller 800 determines the Walsh number for the paging channel by hashing the paging channel number and the unique mobile station number using the unique hashing function, and generates a control message to allocate the paging channel in accordance with the determined Walsh code. The used hash function is identical to the hash function used in the base station. The process for allocating a paging channel in the controller 800 is illustrated in FIG. 9, described further below. The controller 800 provides the Walsh code generator 840 with a control message indicating the Walsh number for the paging channel, and the Walsh code generator 840 then generates the Walsh code corresponding to the Walsh number and supplies the generated Walsh code to the multiplier 810. The multiplier 810 compresses the transmission message Walsh code provided from the Walsh code generator 840. Reverse interleaver 820 inversely interleaves the compressed signal from multiplier 810, and the channel decoder 830 decodes the inverse interleaved signal from inverse interleaver 820 and outputs the bits of decoded information.

 FIG. 9 depicts a procedure for allocating a paging channel in a controller 800. With reference to FIG. 9, a detailed description will be made of a procedure for determining a paging channel, depending on the paging information provided from the base station via the primary paging channel. At operation 900, the controller 800 receives the decoded primary paging message. After that, the controller 800 determines, at step 910, whether or not the decoded primary paging message contains paging information for the IMT-2000 mobile station. When the primary paging message does not contain paging information for the IMT-2000 mobile station, the controller 800 proceeds to step 950 to read the Walsh code number for the IS-95 paging channels from the memory 802. Otherwise, when the primary paging message contains paging information for the IMT- mobile station 2000, the controller 800 proceeds to operation 955 to read the Walsh code number for the IMT-2000 paging channels from the memory 802. Here, the Walsh code number read from the 802 memory is a Walsh pool number.

 Meanwhile, after reading the Walsh numbers in operations 950 and 955, the controller 800 receives its unique number in operation 920. For example, the unique number is stored in memory 802 and displayed when the controller 800 requests. After receiving the unique number, the controller 800 calculates the hashed number using a hash function , at operation 930. The used hash function should be identical to the hash function used in the base station. After calculating the hashed number, the controller 800 determines the Walsh number for allocating the paging channel for the base station in accordance with the calculated hashed number for generating the control message in step 940. The control message is supplied to the Walsh code generator 840 to generate the Walsh code to allocate the paging channel.

 As described above, an IMT-2000 CDMA communication system supporting a variable data rate using a variable Walsh length uses a Walsh code for a direct common channel including a paging channel, which is different from a Walsh code for a direct common IS-95 channel including a paging channel. Thus, an IMT-2000 CDMA communication system supporting a variable data rate can use a short Walsh code, thereby increasing data transfer efficiency. That is, it is possible to efficiently use the limited resources of the Walsh code.

 Although the invention is depicted and described with reference to its specific preferred embodiment, it will be understood by those skilled in the art that various changes in form and details can be made therein without departing from the spirit and scope of the invention as defined by the appended the claims.

Claims (30)

 1. A device for allocating a direct common channel in a CDMA communication system (Code Division Multiple Access), comprising a plurality of channel transmitters, a storage medium for storing, as orthogonal code numbers for a direct common channel used in the second CDMA communication system, orthogonal code numbers that cannot maintain orthogonality due to the orthogonal code that the direct common channel uses at the maximum data rate, and the orthogonal code uses in the first CDMA communication system, and a controller for reading the orthogonal code numbers from the storage medium in accordance with the type information of the mobile station from the mobile station and allocating a specific direct common channel so that the direct common channel message is expanded and transmitted by the corresponding one of the channel transmitters with a specific one of the read numbers of the orthogonal code.  2. The device according to claim 1, characterized in that the storage medium stores the numbers of the orthogonal code generated by sequentially summing the multiple of the lengths of the orthogonal code used at the maximum data rate with the number of the orthogonal code used at the maximum data rate within the full length the orthogonal code, and the number of the orthogonal code used at the maximum data rate.  3. The device according to claim 1, characterized in that the type information of the mobile station is information for identifying the mobile station for the first CDMA communication system and the mobile station for the second CDMA communication system.  4. The device according to claim 1, characterized in that the information about the type of mobile station contains information about the unique number of the mobile station.  5. The device according to claim 3, characterized in that the controller, when determining from the information about the type of the mobile station that the mobile station is intended for the second CDMA communication system, reads from the storage medium the orthogonal codes for the direct common channel stored for the second communication system CDMA, and assigns a specific one of the read numbers of the orthogonal code so that the message of the direct common channel is expanded and transmitted by the corresponding one of the channel transmitters with the assigned number of the orthogonal code.  6. The device according to claim 5, characterized in that the first communication system mdcr is a communication system mdcr IS-95.  7. The device according to claim 6, characterized in that the second communication system mdcr is a communication system mdcr next generation.  8. The device according to claim 4, characterized in that the controller determines the hashed number using a hash function based on the unique number of the mobile station and selects one of the read numbers of the orthogonal code to allocate a direct common channel corresponding to a specific hashed number.  9. A device for allocating a direct common channel in a CDMA communication system (code division multiple access), comprising a plurality of channel receivers, a storage medium for storing, as orthogonal code numbers for a direct common channel used in the second CDMA communication system, orthogonal code numbers which cannot maintain orthogonality due to the orthogonal code that the direct common channel uses at the maximum data rate, and the orthogonal code is used in the first CDMA communication system, and a controller for reading the orthogonal code numbers from the storage medium in accordance with the paging message received from the base station through the primary paging channel, and allocating a specific direct common channel so that the direct common channel message is compressed and transmitted by one channel receivers with a specific one of the read numbers of the orthogonal code.  10. The device according to claim 9, characterized in that the storage medium stores the numbers of the orthogonal code generated by sequentially summing the multiple of the lengths of the orthogonal code used at the maximum data rate with the number of the orthogonal code used at the maximum data rate within the full length the orthogonal code, and the number of the orthogonal code used at the maximum data rate.  11. The device according to claim 9, characterized in that the paging message from the base station contains the number of paging channels.  12. The device according to claim 11, characterized in that the controller, when determining from the paging message that the base station is designed for a second CDMA communication system, reads from the storage medium the orthogonal codes for the direct common channel stored for the second CDMA communication system, and assigns a particular one of the read numbers of the orthogonal code so that the message of the direct common channel is compressed by the corresponding one of the channel receivers with the assigned number of the orthogonal code.  13. The device according to p. 12, characterized in that the first communication system mdcr is a communication system mdcr IS-95.  14. The device according to item 13, wherein the second communication system mdcr is a communication system mdcr next generation.  15. The device according to claim 11, characterized in that the controller determines the hashed number using a hash function based on the number of paging channels and the unique number of the mobile station included in the paging message, and selects one of the read orthogonal code numbers to highlight the direct common a channel corresponding to a specific hashed number.  16. A method for allocating a direct common channel in a CDMA communication system (code division multiple access) comprising a plurality of channel transmitters, comprising storing, as the numbers of the orthogonal code for the direct common channel used in the second CDMA communication system, the orthogonal number codes that cannot maintain orthogonality due to the orthogonal code that the direct common channel uses at the maximum data rate, and the orthogonal code is used in the first system CDMA communication, and read the numbers of the orthogonal code in accordance with the type information of the mobile station from the mobile station and allocate a specific direct common channel so that the direct common channel message is expanded and transmitted by one of the channel transmitters with a specific one of the read orthogonal code numbers .  17. The method according to clause 16, characterized in that the stored numbers of the orthogonal code contain the numbers of the orthogonal code generated by sequentially summing the multiple of the lengths of the orthogonal code used at the maximum data rate with the number of the orthogonal code used at the maximum data rate within the full length of the orthogonal code, and the number of the orthogonal code used at the maximum data rate.  18. The method according to clause 16, wherein the type information of the mobile station is information for identifying the mobile station for the first CDMA communication system and the mobile station for the second CDMA communication system.  19. The method according to clause 16, wherein the type information of the mobile station contains information about the unique number of the mobile station.  20. The method according to p. 18, characterized in that when determining from the type information of the mobile station that the mobile station is for the second CDMA communication system, the orthogonal codes for the direct common channel stored for the second CDMA communication system are read and a specific one of the read numbers of the orthogonal code so that the message of the direct common channel is compressed and transmitted by the corresponding one of the channel transmitters with the assigned number of the orthogonal code.  21. The method according to claim 20, characterized in that the first communication system mdcr is a communication system mdcr IS-95.  22. The method according to p. 21, characterized in that the second communication system mdcr is a communication system mdcr next generation.  23. The method according to claim 19, characterized in that it further determines the hashed number using a hash function based on the unique number of the mobile station and selects one of the read orthogonal code numbers to allocate a direct common channel corresponding to the determined hashed number.  24. A method for allocating a direct common channel in a CDMA communication system (Code Division Multiple Access) comprising a plurality of channel receivers, which consists in storing, as the numbers of the orthogonal code for the direct common channel used in the second CDMA communication system, the orthogonal number codes that cannot maintain orthogonality due to the orthogonal code that the direct common channel uses at the maximum data rate, and the orthogonal code is used in the first system CDMA communication, and read the numbers of the orthogonal code from the storage medium in accordance with the paging message received from the base station through the primary paging channel, and allocate a specific direct common channel so that the direct channel information is compressed and transmitted by one of the channel receivers with specific one of the read numbers of the orthogonal code.  25. The method according to paragraph 24, wherein the stored numbers of the orthogonal code contain the numbers of the orthogonal code generated by sequentially summing the multiple of the lengths of the orthogonal code used at the maximum data rate with the number of the orthogonal code used at the maximum data rate within the full length of the orthogonal code, and the number of the orthogonal code used at the maximum data rate.  26. The method according to paragraph 24, wherein the paging message from the base station contains the number of paging channels.  27. The method according to p. 26, characterized in that when determining from the paging message that the base station is designed for the second communication system mdcr, read the orthogonal codes for the direct common channel stored for the second communication system mdcr, and assign a specific one of the read orthogonal code numbers so that the forward common channel message is compressed by the corresponding one of the channel receivers with the assigned orthogonal code number.  28. The method according to p. 27, characterized in that the first communication system mdcr IS-95.  29. The method according to p. 28, wherein the second communication system mdcr is a communication system mdcr next generation.  30. The method according to p. 26, characterized in that the hashed number is determined using the hash function based on the number of paging channels and the unique number of the mobile station included in the paging message, and one of the read orthogonal code numbers is selected to allocate a direct common channel corresponding to a specific hashed number.

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